DK165809B - Method of compensating for offset voltage in a regulating amplifier and circuit arrangement for implementation of the method - Google Patents

Description

DK 165809B

in

The present invention relates to a method for offsetting the offset voltage by a control amplifier.

Regulatory amplifiers, e.g. used in the focus and track control circuits by optical sensing systems in CD recorders. For CD recorders, the utility signals, e.g. audio or video signals stored on a CD in spiral or circular data tracks, read out by an optical system. The optical system usually consists of a lens device whose lenses are displaced in the axial direction by means of the focus control circuit so that the focal point of the lens device lies on the CD. This is called the regulation process, which in principle corresponds to the sharpness setting of a binoculars, focusing. In order for the utility signals to be read out flawlessly from the CD using the optical system, a permanent focus is required by the focus control circuit. Since 15 already small deviations from the sharpness setting lead to errors in reading the utility signals stored on the CD, the offset voltage of the control amplifier must not be too large. It must therefore be compensated.

The object of the invention is to provide a method 20 for compensating the offset voltage of a control amplifier.

According to the invention, this is achieved by measuring the offset compensation voltage to the output of the regulating amplifier separated from the regulating unit's regulating unit, storing the value of the offset compensation voltage, the output of the regulating amplifier being measured and storing the offset compensation voltage offset compensation voltage is fed to the input of the control amplifier.

The invention will now be explained in more detail with reference to the drawing, in which fig. 1 and 2 show circuit devices for carrying out the method according to the invention.

The method according to the invention will be explained by means of the embodiment of FIG. 1 and the circuit device shown in claim 2.

35 In FIG. 1, the output of the control amplifier RV is connected to the input of an analog-digital converter AD and to one switch on a controllable switch S, the other of which is connected to the control unit SG. At the input of the control amplifier RV is the control signal F of the control unit SG. The output of 2

DK 165809B

the analog-digital converter AD is connected to a first input E1 on a control circuit ST. A first output A1 of the control circuit ST is connected to the input of a forward-reverse counter Z, the output of which is connected to the input of a digital-analog converter DA. The output 5 of the digital-to-analog converter DA is connected to the input of the control amplifier RV. On another input E2 on the control circuit ST lies the offset reference voltage. Another output A2 of the control circuit ST is connected to the control input of the controllable switch S.

10 It will now be explained how the circuit device of FIG. 1, which e.g. may be built into a CD record player, works.

When the CD-player is switched on, the control circuit ST causes the controllable switch S and thereby also the focus control circuit to be opened. In open focus control circuit, the analog 15 offset voltage at the output of the control amplifier RV over the analog / digital converter AD in digital form is fed to the control circuit ST, in which the offset voltage is compared with the offset reference voltage - usually 0 V. The control circuit ST gives counting pulses. the reverse counter Z when the offset voltage at the output of the 20 control amplifier RV does not match the offset reference voltage of 0 V. The numerical value at the output of the counter Z is converted in the digital analogue converter DA to an analog voltage which is fed back to the input of the control amplifier RV and compensates offset voltage because the forward-reverse counter Z from the control-25 circuit ST receives counting pulses until the offset voltage becomes zero.

If the offset voltage at the output of the control amplifier RV is compensated, the control circuit ST closes the controllable switch S, so that the focus control circuit is again closed and the focal point of the lens device thus lies on the plate. Furthermore, from this point on, the control circuit ST outputs no additional counting pulses to the forward-reverse counter Z, so that the value of the compensation voltage is stored in it. Above the digital-analog converter DA, this compensation voltage is permanently at the input of the control amplifier RV in analog form. When the CD recorder 35 is switched off and switched on again, the controllable switch S is re-opened as just described, the compensation voltage is determined, stored and in analog form applied to the input of the control amplifier RV.

In FIG. 2 shows a further circuit device for exercise 3

DK 165809 B

of the process of the invention.

At the input of the control amplifier RV is the control signal F of the control unit SG. The output of the control amplifier RV is connected to the inverting input of an operational amplifier OP and to the one contact of a controllable switch S whose other contact is connected to the input of the control unit SG. The control input of the operational amplifier OP is connected to the input E of a microprocessor μΡ and above a first resistor R1 with the non-inverting input of the operational amplifier, which above a second resistor R2 is at reference potential. A first output A1 of the microprocessor mP is connected to the control input of the controllable switch S. A second output A2 of the microprocessor mP is connected to the input of an impulse width module ator P, the output of which is connected to the input of an integrator I. the torque I is connected to the input of the control amplifier RV.

In the following, the operation of the circuit device of FIG. 2nd

As with the circuit device of FIG. 1, the focus control circuit at the switch-on of the apparatus is opened by the microprocessor μΡ 20 opening the controllable switch S by means of a signal which it emits at its first output A1. The operational amplifier OP together with the first and second resistors R1 and R2 form a comparator K in which the offset voltage is compared with the offset reference voltage. The microprocessor μΡ changes the voltage at its second output 25 A2 until the offset voltage at the output of the control amplifier RV matches the offset reference voltage, ie. until the offset voltage is compensated. In the microprocessor μΡ, the value of the voltage is now stored, which value compensates the offset voltage at the output of the control amplifier RV. In addition, at its first output A1, the microprocessor μΡ outputs a signal which in turn terminates the controllable switch S and thus also the focus control circuit. Above the pulse width modulator P and integrator I, the compensation voltage is now permanently at the output of the control amplifier RV. With each reconnection of the apparatus, the offset voltage is again compensated just as with the one shown in FIG. 1.

The pulse width modulator P may be integrated into the microprocessor μΡ or provided by software in the microprocessor μΡ.

An advantage of the invention consists in that in the manufacture

DK 165809 B

4 of CD record players whose focus control circuit operates in accordance with the method of the invention, no more adjustment of the control amplifier is required. Since the offset voltage is recompensed each time the appliance is switched on, operation of the offset voltage over a long period of time due to the aging of the components does not produce any impact.

Therefore, it cannot occur that the control amplifier in the focus control circuit of a CD record player, which initially played flawlessly, but where the sound quality after noticeably decreased noticeably, has to be re-adjusted in the workshop. The omission of such maintenance measures by appliances whose control circuits operate according to the method of the invention is to be regarded as an additional advantage, as the maintenance of an apparatus is not only unpleasant to the customers, but also costs money.

15 20 25 1 35

Claims (7)

A method of offset voltage compensation in a control amplifier (RV), characterized in that for measurement 5 of the offset compensation voltage, the output of the control amplifier (RV) is separated from the control circuit, regulating unit (SG), the value of the offset compensation voltage is stored ( RV) is again connected to the control unit's control unit (SG) after measuring and storing the offset compensation voltage and the stored offset compensation voltage is fed back to the input of the control amplifier (RV). Circuit device for carrying out the method according to claim 1, characterized in that the control signal (F) of the control unit (SG) is at the input of the control amplifier (RV), that the output of the control amplifier (RV) is connected to the input of an analogue digital converter (AD) and with one switch in a controllable switch (S), the second switch of which is connected to the control unit (SG), that the output of the analog-digital converter (AD) is connected to a first input (E1) on a control circuit (ST) that a first output (A1) of the control circuit (ST) is connected to the input of a forward-reverse counter (Z), that the output of the forward-reverse counter (Z) is connected to the input of a digital analog converts (DA) whose output is connected to the input of the control amplifier (RV) that the offset reference voltage is at another input (E2) of the control circuit (ST) and that another output (A2) of the control circuit (ST) is Federal one with the control input of the controllable switch (S). Circuit device according to claim 2, characterized in that the digital-analog converter (DA) is constructed as a series connection of an impulse module ator (P) and integrator (I). Circuit device for carrying out the method according to claim 1, characterized in that the control signal (F) of the control unit (SG) is on the input of the control amplifier (RV), that the output of the control amplifier (RV) is connected to the inverting input of an operational amplifier (OP) and with one switch in a controllable switch (S), the other switch of which is connected to the input of the control unit (SG), that the output of the operational amplifier (OP) is connected to an input (E) of a 6 DK 165809 B microprocessor (μΡ) and above a first resistor (RI) with the non-inverting input of the operational amplifier, the non-inverting input of the operational amplifier (OP) above a second resistor (R2) is at the reference potential that a first output (A1) of the microprocessor (μΡ) is connected to the control input of the controllable switch (S), another output (A2) of the microprocessor (μΡ) is connected to the input of an impu module module ator (P) whose output is connected to the input of an integrator (I) and the output of the integrator (I) is connected to the input of the control amplifier (RV). Circuit device according to claim 3 or 4, characterized in that the pulse module ator (P) is a pulse width module ator. Circuit device according to claim 4 or 5, characterized in that the pulse module ator (P) is integrated into the microprocessor 15 (μΡ). Circuit device according to claim 4 or 5, characterized in that the pulse module ator (P) is performed by software in the microprocessor (μΡ). 20 25 30 35